'''WIP --- Doesn't work well yet''' import plac import random import six import cProfile import pstats import pathlib import cPickle as pickle from itertools import izip import spacy import cytoolz import cupy as xp import cupy.cuda import chainer.cuda import chainer.links as L import chainer.functions as F from chainer import Chain, Variable, report import chainer.training import chainer.optimizers from chainer.training import extensions from chainer.iterators import SerialIterator from chainer.datasets import TupleDataset class SentimentAnalyser(object): @classmethod def load(cls, path, nlp, max_length=100): raise NotImplementedError #with (path / 'config.json').open() as file_: # model = model_from_json(file_.read()) #with (path / 'model').open('rb') as file_: # lstm_weights = pickle.load(file_) #embeddings = get_embeddings(nlp.vocab) #model.set_weights([embeddings] + lstm_weights) #return cls(model, max_length=max_length) def __init__(self, model, max_length=100): self._model = model self.max_length = max_length def __call__(self, doc): X = get_features([doc], self.max_length) y = self._model.predict(X) self.set_sentiment(doc, y) def pipe(self, docs, batch_size=1000, n_threads=2): for minibatch in cytoolz.partition_all(batch_size, docs): minibatch = list(minibatch) sentences = [] for doc in minibatch: sentences.extend(doc.sents) Xs = get_features(sentences, self.max_length) ys = self._model.predict(Xs) for sent, label in zip(sentences, ys): sent.doc.sentiment += label - 0.5 for doc in minibatch: yield doc def set_sentiment(self, doc, y): doc.sentiment = float(y[0]) # Sentiment has a native slot for a single float. # For arbitrary data storage, there's: # doc.user_data['my_data'] = y class Classifier(Chain): def __init__(self, predictor): super(Classifier, self).__init__(predictor=predictor) def __call__(self, x, t): y = self.predictor(x) loss = F.softmax_cross_entropy(y, t) accuracy = F.accuracy(y, t) report({'loss': loss, 'accuracy': accuracy}, self) return loss class SentimentModel(Chain): def __init__(self, nlp, shape, **settings): Chain.__init__(self, embed=_Embed(shape['nr_vector'], shape['nr_dim'], shape['nr_hidden'], set_vectors=lambda arr: set_vectors(arr, nlp.vocab)), encode=_Encode(shape['nr_hidden'], shape['nr_hidden']), attend=_Attend(shape['nr_hidden'], shape['nr_hidden']), predict=_Predict(shape['nr_hidden'], shape['nr_class'])) self.to_gpu(0) def __call__(self, sentence): return self.predict( self.attend( self.encode( self.embed(sentence)))) class _Embed(Chain): def __init__(self, nr_vector, nr_dim, nr_out, set_vectors=None): Chain.__init__(self, embed=L.EmbedID(nr_vector, nr_dim, initialW=set_vectors), project=L.Linear(None, nr_out, nobias=True)) self.embed.W.volatile = False def __call__(self, sentence): return [self.project(self.embed(ts)) for ts in F.transpose(sentence)] class _Encode(Chain): def __init__(self, nr_in, nr_out): Chain.__init__(self, fwd=L.LSTM(nr_in, nr_out), bwd=L.LSTM(nr_in, nr_out), mix=L.Bilinear(nr_out, nr_out, nr_out)) def __call__(self, sentence): self.fwd.reset_state() fwds = map(self.fwd, sentence) self.bwd.reset_state() bwds = reversed(map(self.bwd, reversed(sentence))) return [F.elu(self.mix(f, b)) for f, b in zip(fwds, bwds)] class _Attend(Chain): def __init__(self, nr_in, nr_out): Chain.__init__(self) def __call__(self, sentence): sent = sum(sentence) return sent class _Predict(Chain): def __init__(self, nr_in, nr_out): Chain.__init__(self, l1=L.Linear(nr_in, nr_in), l2=L.Linear(nr_in, nr_out)) def __call__(self, vector): vector = self.l1(vector) vector = F.elu(vector) vector = self.l2(vector) return vector class SentenceDataset(TupleDataset): def __init__(self, nlp, texts, labels, max_length): self.max_length = max_length sents, labels = self._get_labelled_sentences( nlp.pipe(texts, batch_size=5000, n_threads=3), labels) TupleDataset.__init__(self, get_features(sents, max_length), labels) def __getitem__(self, index): batches = [dataset[index] for dataset in self._datasets] if isinstance(index, slice): length = len(batches[0]) returns = [tuple([batch[i] for batch in batches]) for i in six.moves.range(length)] return returns else: return tuple(batches) def _get_labelled_sentences(self, docs, doc_labels): labels = [] sentences = [] for doc, y in izip(docs, doc_labels): for sent in doc.sents: sentences.append(sent) labels.append(y) return sentences, xp.asarray(labels, dtype='i') class DocDataset(TupleDataset): def __init__(self, nlp, texts, labels): self.max_length = max_length DatasetMixin.__init__(self, get_features( nlp.pipe(texts, batch_size=5000, n_threads=3), self.max_length), labels) def read_data(data_dir, limit=0): examples = [] for subdir, label in (('pos', 1), ('neg', 0)): for filename in (data_dir / subdir).iterdir(): with filename.open() as file_: text = file_.read() examples.append((text, label)) random.shuffle(examples) if limit >= 1: examples = examples[:limit] return zip(*examples) # Unzips into two lists def get_features(docs, max_length): docs = list(docs) Xs = xp.zeros((len(docs), max_length), dtype='i') for i, doc in enumerate(docs): j = 0 for token in doc: if token.has_vector and not token.is_punct and not token.is_space: Xs[i, j] = token.norm j += 1 if j >= max_length: break return Xs def set_vectors(vectors, vocab): for lex in vocab: if lex.has_vector and (lex.rank+1) < vectors.shape[0]: lex.norm = lex.rank+1 vectors[lex.rank + 1] = lex.vector else: lex.norm = 0 return vectors def train(train_texts, train_labels, dev_texts, dev_labels, lstm_shape, lstm_settings, lstm_optimizer, batch_size=100, nb_epoch=5, by_sentence=True): nlp = spacy.load('en', entity=False) if 'nr_vector' not in lstm_shape: lstm_shape['nr_vector'] = max(lex.rank+1 for lex in nlp.vocab if lex.has_vector) if 'nr_dim' not in lstm_shape: lstm_shape['nr_dim'] = nlp.vocab.vectors_length print("Make model") model = Classifier(SentimentModel(nlp, lstm_shape, **lstm_settings)) print("Parsing texts...") if by_sentence: train_data = SentenceDataset(nlp, train_texts, train_labels, lstm_shape['max_length']) dev_data = SentenceDataset(nlp, dev_texts, dev_labels, lstm_shape['max_length']) else: train_data = DocDataset(nlp, train_texts, train_labels) dev_data = DocDataset(nlp, dev_texts, dev_labels) train_iter = SerialIterator(train_data, batch_size=batch_size, shuffle=True, repeat=True) dev_iter = SerialIterator(dev_data, batch_size=batch_size, shuffle=False, repeat=False) optimizer = chainer.optimizers.Adam() optimizer.setup(model) updater = chainer.training.StandardUpdater(train_iter, optimizer, device=0) trainer = chainer.training.Trainer(updater, (1, 'epoch'), out='result') trainer.extend(extensions.Evaluator(dev_iter, model, device=0)) trainer.extend(extensions.LogReport()) trainer.extend(extensions.PrintReport([ 'epoch', 'main/accuracy', 'validation/main/accuracy'])) trainer.extend(extensions.ProgressBar()) trainer.run() def evaluate(model_dir, texts, labels, max_length=100): def create_pipeline(nlp): ''' This could be a lambda, but named functions are easier to read in Python. ''' return [nlp.tagger, nlp.parser, SentimentAnalyser.load(model_dir, nlp, max_length=max_length)] nlp = spacy.load('en') nlp.pipeline = create_pipeline(nlp) correct = 0 i = 0 for doc in nlp.pipe(texts, batch_size=1000, n_threads=4): correct += bool(doc.sentiment >= 0.5) == bool(labels[i]) i += 1 return float(correct) / i @plac.annotations( train_dir=("Location of training file or directory"), dev_dir=("Location of development file or directory"), model_dir=("Location of output model directory",), is_runtime=("Demonstrate run-time usage", "flag", "r", bool), nr_hidden=("Number of hidden units", "option", "H", int), max_length=("Maximum sentence length", "option", "L", int), dropout=("Dropout", "option", "d", float), learn_rate=("Learn rate", "option", "e", float), nb_epoch=("Number of training epochs", "option", "i", int), batch_size=("Size of minibatches for training LSTM", "option", "b", int), nr_examples=("Limit to N examples", "option", "n", int) ) def main(model_dir, train_dir, dev_dir, is_runtime=False, nr_hidden=64, max_length=100, # Shape dropout=0.5, learn_rate=0.001, # General NN config nb_epoch=5, batch_size=32, nr_examples=-1): # Training params model_dir = pathlib.Path(model_dir) train_dir = pathlib.Path(train_dir) dev_dir = pathlib.Path(dev_dir) if is_runtime: dev_texts, dev_labels = read_data(dev_dir) acc = evaluate(model_dir, dev_texts, dev_labels, max_length=max_length) print(acc) else: print("Read data") train_texts, train_labels = read_data(train_dir, limit=nr_examples) dev_texts, dev_labels = read_data(dev_dir, limit=nr_examples) print("Using GPU 0") #chainer.cuda.get_device(0).use() train_labels = xp.asarray(train_labels, dtype='i') dev_labels = xp.asarray(dev_labels, dtype='i') lstm = train(train_texts, train_labels, dev_texts, dev_labels, {'nr_hidden': nr_hidden, 'max_length': max_length, 'nr_class': 2, 'nr_vector': 5000}, {'dropout': 0.5, 'lr': learn_rate}, {}, nb_epoch=nb_epoch, batch_size=batch_size) if __name__ == '__main__': #cProfile.runctx("plac.call(main)", globals(), locals(), "Profile.prof") #s = pstats.Stats("Profile.prof") #s.strip_dirs().sort_stats("time").print_stats() plac.call(main)